ANALYSIS OF STRUCTURE BEHAVIOUR OF DOMES
NUR NADIA AMIRA BINTI ROSELY
Report submitted in partial fulfillment of the requirements
for the award of the degree of
Bachelor (Hons.) of Civil Engineering
Faculty of Civil Engineering and Earth ResourceUNIVERSITI MALAYSIA PAHANG
JULY 2015
v
ABSTRACT
This study is about the analysis structural behaviour in domes. Generally important todefine the concept concerning the loss of stability and the method to determine the collapseload of the structure. As single layer dome show an important nonlinear behaviour withconsiderable softening. The purpose of this research is to analyse the several type of domesusing Formian the programming language of formex algebra to evaluate the structuralbehaviour by import the formex file into finite element software LUSAS analysisprogramming. In this research, will included the comparison between five models of domeswith the same span, rise, sweep angle, radius and central angle in term structure behaviour.The structure behaviour involve are maximum buckling, maximum starin and maximumstress. The type of dome that were used are a ribbed dome, two schwedler domes and twolamella domes with same specification. Various type of configuration pattern of dome willbe used to analyse.
vi
ABSTRAK
Kajian ini adalah mengenai analisis kelakuan struktur dalam kubah. Secara umumnyapenting untuk menentukan konsep mengenai kehilangan kestabilan dan kaedah untukmenentukan beban runtuh struktur. Sebagai kubah lapisan tunggal, menunjukkan tingkahlaku tidak linear penting dengan penurunan yang agak besar. Tujuan kajian ini adalahuntuk menganalisis beberapa jenis kubah menggunakan Formian bahasa pengaturcaraanalgebra formex untuk menilai tingkah laku struktur oleh import fail formex kepada perisianunsur pengaturcaraan analisis LUSAS. Dalam kajian ini, perbandingan dari sudut kelakuanstruktur antara lima model kubah dengan lebar yang sama, ketinggian yang sama, sudutjejari yang sama dan sudut pusat yang sama. Kelakuan struktur yang terlibat adalahlengkungan maksimum, strain maksimum dan tegasan maksimum. Jenis kubah yangdigunakan adalah satu kubah ribbed, dua kubah schwedler dan dua kubah lamella denganspesifikasi yang sama. Jenis Pelbagai corak konfigurasi kubah akan digunakan untukmenganalisis.
vii
TABLE OF CONTENT
Page
SUPERVISOR'S DECLARATION i
STUDENT'S DECLARATION ii
DEDICATION iii
ACKNOLEWDGEMENT iv
ABSTRACT v
ABSTRAK vi
TABLE OF CONTENTS vii
LIST OF TABLES x
LIST OF FIGURES xi
LIST OF APPENDICES xiii
LIST OF SYMBOLS xiv
CHAPTER 1 INTRODUCTION
1.1 Background of Study 1
1.2 Problem Statement 2
1.3 Objectives 3
1.4 Scope of Study 4
1.5 Significant of Study 5
CHAPTER 2 LITERATURE REVIEW
2.1 Introduction 6
2.2 Dome
2.2.1 Ribbed Dome2.2.2 Schwedler Dome2.2.3 Lamella Dome
7
101011
2.3 Grid 12
viii
2.3.1 Two-way Grid2.3.2 Three-way Grid2.3.3 Four-way Grid
131314
2.4 Domes Design Analysis
2.4.1 Wind Load2.4.2 Dead Load2.4.3 Fabric Cover Load
15
151616
2.5 Dome Behaviour
2.5.1 Non-Linear Buckling Analysis2.5.1.1 Factor Influencing The Buckling Load
2.5.2 Stress Analysis2.5.3 Strain Analysis
16
18181920
2.6 Space Structure System
2.6.1 Nodular System
2.6.1.1 Ball Joint System2.6.1.2 Socket Joint System2.6.1.3 Plate Joint System2.6.1.4 Slot Joint System2.6.1.5 Shell Joint System
2.6.2 Modular System
2.6.2.1 Space Deck System2.6.2.2 Unibat System2.6.2.3 Cubic System
2.6.3 Compositive System
2.6.2.1 Space Deck System
20
20
2121212122
22
222323
23
23
CHAPTER 3 METHODOLOGY
3.1 Introduction 24
3.2 Flow Chart of Project Methodology 25
3.3 Formian Programming
3.3.1 Modelling Using Formian3.3.2 Define The Element3.3.2 Define The Element
27
293031
3.4 LUSAS Software
3.4.1 Import File
32
33
ix
3.4.2 Analyse the dome 33
CHAPTER 4 RESULT AND DISCUSSION
4.1 Introduction 38
4.2 Result
4.2.1 Ribbed Dome Analysis4.2.2 Lamella Dome 1 Analysis4.2.3 Lamella Dome 2 Analysis4.2.4 Schwedler Dome 1 Analysis4.2.5 Schwedler Dome 2 Analysis
39
3939404141
4.3 Analysis
4.3.1 Maximum Buckling Analysis4.3.2 Maximum Stress Analysis4.3.3 Maximum Strain Analysis
43
434445
4.4 Result Comparison 45
CHAPTER 5 CONCLUSION AND RECOMENDATION
5.1 Introduction 47
5.2
5.3
5.4
Conclusion Based On Objective
5.2.1 Objective 15.2.2 Objective 2
Conclusion Based On Analysis
Recommendation
47
4748
48
49
REFERENCES 51
APPENDICES 53
A Ribbed Dome 53
B Lamella Dome 1 55
C Lamella Dome 2 57
D Schwedler Dome 1 59
E Schwedler Dome 2 61
x
LIST OF TABLES
Table No. Title Page
4.1 Maximum buckling, maximum stress and maximum strain of Ribbed
Dome
41
4.2 Maximum buckling, maximum stress and maximum strain of Lamella
Dome 1
42
4.3 Maximum buckling, maximum stress and maximum strain of Lamella
Dome 2
42
4.4 Maximum buckling, maximum stress and maximum strain of Schwedler
Dome 1
43
4.5 Maximum buckling, maximum stress and maximum strain of Schwedler
Dome 2
44
4.6
5.1
Maximum buckling, maximum stress and maximum strain comparison
Comparison in shape of grid pattern
48
51
xi
LIST OF FIGURES
Table No. Title Page
2.1 Nagoya Dome, Japan 7
2.2 The Bloudel Conservatory, Queen Elizabeth Park, Vancouver/Canada 8
2.3 Ribbed Domes 9
2.4 Schwedler Domes 9
2.5 Lamella Domes 9
2.6 Blackpool Cox Dome 10
2.7 Cinesphere - Ontario Place 11
2.8
2.9
2.10
2.11
2.12
2.13
2.14
2.15
2.16
Stadium in Houston, Texas
Astrodome (Steel Lamella Dome), Houston/USA
Rectangular grid
Diagonal grid
Triangular grid
Hexagonal grid
Combination rectangular and triangle grid
Single-layer grid dome
Non-linear vs. eigenvalue buckling behaviour
12
12
13
13
14
14
14
17
18
3.1 Project flow chart 27
3.2 (a) Formian Programming Software 28
3.3 Lusas Analysis Software 29
3.4 Ribbed Dome 30
3.5 Lamella Dome 1 30
3.6 Lamella Dome 2 30
3.7 Schewdler Dome 1 31
3.8 Schwedler Dome 2 31
3.9 Formian Screen 32
3.10 Processing of a Ribbed Dome 33
3.11 Formulation of a Ribbed Dome 33
xii
3.12 Formulation of a Lamella Dome 34
3.13 Formulation of a Schwedler Dome 34
3.14(a) First step in import file 35
3.14(b) Second step in import file 35
3.15 Create a project step 36
3.16(a) First step in selection of mesh attributes 36
3.16(b) Second step in selection of mesh attributes 36
3.17(a) First step in selection of geometric section 37
3.17(b) Second step in selection of geometric section 37
3.17(c) Third step in selection of geometric section 38
3.18 Selection of structure material 38
3.19 Selection of structure support 38
3.20 Specify the loading for the structure 39
4.1 Maximum buckling of Ribbed dome, Lamella dome 1, Lamella dome
2, Schwedler dome 1 and Schwedler dome 2
45
4.2 Maximum stress of Ribbed dome, Lamella dome 1, Lamella dome 2,
Schwedler dome 1 and Schwedler dome 2
46
4.3 Maximum strain of Ribbed dome, Lamella dome 1, Lamella dome 2,
Schwedler dome 1 and Schwedler dome 2
47
xiii
APPENDICES
A Ribbed Dome 54
B Lamella Dome 1 56
C Lamella Dome 2 58
D Schwedler Dome 1 60
E Schwedler Dome 2 62
xiv
LIST OF SYMBOLS
σ - Stress
ε - Strain
1
CHAPTER 1
INTRODUCTION
1.1 BACKGROUND OF STUDY
A space structure is a network of structural frame members, such as tubes and
interconnected the member connection points which is commonly called as nodes. Therefore,
the whole structure behaves as one structural element which is difference in the typical
framing members of beams and columns, as in building, structural elements will completely
separately force paths and often act independently on each other.
A space structure refers to a structural system where the load transfer mechanism that
involves three dimensions. It is can be used in the large span areas with minor interior
supports, such as regularly seen as mosque domes. Besides, space structure is strong because
of the triangle inherent rigidity. Hence, variety type of space structure can be illustrated by
using the Formian which is the conceptual tool for computer aided processing, in order to
analyse the space structure configuration.
In structural engineering, a space structural also known as space frame which is a
truss-like, lightweight structure that connected from interlocking struts. Thus, it is a
necessary to ensure the space structure connection system are satisfactory the requirement of
design. There are several types of connector or joint in term of prefabricated of space
structure system which are called as nodular, modular and compositive. Meanwhile, the strut
members are interconnected at spaced apart nodes in the frame. The flexing loads or the
bending moments are transfer as tension and compression loads along the length of each
2
strut. A dome is a space structure covering more or less curvature square or circular area. As
for single layer dome space structures are regularly used in moderate span of buildings, sport
halls and exhibition centers. The structural system consists of elements that are arched in all
direction. The best known example is the Dome of Revolution. It is one of the earliest sphere
segment of the shell structure which is built in roman times and formed by a surface generated
by a curve of any form revolting about a vertical line.
A dome can be split up to two different direction which are, vertical section separated
by longitudinal arch lines also called as meridians and horizontal sections separated by hoops
or parallels. The structural behavior of the structure is similar as the arches under uniform
loading, the dome is also under compression everywhere and the stresses act along the arch
and the hoop lines. To define the different between types of domes, the comparison need to
be analye in term of the structural behavior.
In this research, there are include the studies of formian which is to illustrate the
domes type of space structure in order to proceed the analysis on the structure behavior.
Formian is known as programming language of formex algebra. The term configuration mean
that the arrangement of parts, which is can be described using a numerical model. So, the
configuration processing can be explain as the creation or manipulation of numerical models
that represent configuration. It is a convenient medium of using the concepts of formex
configuration processing will be used to illustrate the configuration as the analysis.
1.2 PROBLEM STATEMENT
Nowadays, space structures are often built all over the world such as sport stadiums,
culture centers, aircraft hangers, leisure centers, radio telescopes, railway stations, shopping
malls, auditoriums and gymnasiums. These paces mentioned generally kind of place that
demand a wide area without column in between the structure. Therefore, an issues would
arise upon the numerous design of structure which need an architect to design in particular
type of building structure. The search for new structural forms to accommodate wide
3
unobstructed areas will be main objective of engineers and architects. To avoid these issues,
space structure shall be the key of the building structure that demand a free column in the
large area.
In order to build these building structure, the skeletal space frame which are three-
dimensional structures need to be capable in free column long span. The structures
constructed from either individual elements or prefabricated modules possess a high strength
to weight ratio and high inherent stiffness. Therefore, to provide complete freedom in large
span areas while providing strong resistance, there are a structural solution called space
structure.
Uncountable progress had done in the process of the development of the space
structure. A huge amount of experimental and theoretical research programs was carried out.
As a result, a great deal of useful information has been disseminated and fruitful results have
been put into practice. With the appearance of new building techniques and construction
materials, space structure currently provide the right answer and satisfy the requirements for
large area without column, great structural potential and visual beauty.
1.3 OBJECTIVE
i. To study the formex Configuration Progressing on how to arrange the part of formex
algebra called Formian the programming language of formex algebra.
ii. To analyse the several type of domes, by using the finite element software LUSAS
programming analysis to evaluate the structural behaviours.
4
1.4 SCOPE OF STUDY
The space structure consist many form of configuration such as domes and barrel
vaults. In this research will focusing on domes form of configuration. The analyses need to
be perform for the type of domes using Formian the programming language of formex
algebra to illustrate the composite transformations. The type of domes that will be analyse
are ribbed dome, lamella dome and schwedler dome.
The scope of this research will covered the study about the basic concept of the
Formex Configuration Processing on how to arrange the parts of formex algebra. Formex
algebra itself as a mathematical system that provides simple tools mathematical system as
stated by Noorshin H. and Disney P (2000). Therefore, it is required to study Formex
Configuration Processing as convenient medium for configuration processing to illustrate the
ribbed dome, lamella dome and schwedler dome.
To analyse these three type of domes, the same particular of the dome will be used,
which is the span (S) is 40 meter, the rise (H) is 7 meter, the sweep angle (A) is 43 degree,
the radius (R) is 30 meter and the central angle of the dome is twice the sweep angle equal
to 86 degree. To compare the structural behavior of the dome in term of buckling. The types
of buckling concerned here are the general buckling, the local buckling and the buckling of
a member. In these analysis, the geometrical nonlinearity due to large displacements will be
included.
Lastly, the research will include the study about type of connector or joint in term of
prefabricated of space structure system which are called as nodular, modular and
compositive. As for the nodular system, the main components are joint and elements such as
ball ball joint system, socket joint system, plate joint system, slot joint system and shell joint
system. Meanwhile, as for the modular system, consists of prefabricated basic units such as
space deck system, unibat system and cubic system. As for compositive system do not has
any particular joint components which has no specific ‘node piece’ or ‘unit’. In space
5
structure system, each prefabricated space structure system had their relative advantages and
disadvantages. The type of joint depends primarily on the connection techniques and also
affected by the shape of the members, angle or wide flange. Therefore, as the prefabricated
type connection of the joint, it is necessary need to be choose the most suitable for the
particular structure.
1.5 SIGNIFICANT OF STUDY
The outcomes predicted from this research is to increase the achievement of
development construction for residential, commercial or public purposes, by providing a
column-free space with the most efficient domes. The efficiency of different type of domes,
that is ribbed dome, schwedler dome and lamella dome will be compare through their
structural behaviour. Besides that, the chosen of connector shall be most suitable and
essential as the number of units and connections should be the minimized. In addition, the
outcome from the research is to provide a research guide to the young engineer in the future.
6
CHAPTER 2
LITERATURE REVIEW
2.1 INTRODUCTION
Space structure commonly involve three dimension of structural system. The space
structure idealized is extend beyond a single plane, in term of the combination of
configuration, external loads, internal forces and displacement. Meanwhile in single plane,
the external loads and internal forces of plane structure contains the structure itself, both in
its initial unloaded state and in its deformed loaded state. It is shows that the plane structure
is completely contrast with space structure. As in practice, the space structure form is used
to refer to the number of families of structures such as grids, tower, cable, net membrane
system, and foldable assembly and tensegrity forms.
Space structures cover an enormous range of shapes and are constructed using
different materials such as steel, aluminium, timber, concrete, fibre reinforced composite,
glass, or a combination of these. As for this research, the material that were chose to apply
in the analysis is mild steel. The introduction of steel, with its greatly improved properties of
high strength, proved to be a fundamental influence in the development of various types of
braced dome and their use for large spans.
Space structures may be divided into three categories that are lattice space structures,
continuous space structures and biform space structure. Space structure forms are at the
centre of attention in the present paper an overview of space structure form with emphasis
on the geometric characteristics of lattice space structure. Lattice space structures describe
7
as structure that consist of discrete, normally elongated element such as barrel vaults and
domes. In particular, this research will overview the domes type of lattice space structures.
2.2 DOMES
Domes had the advantage of providing an easy and economic method of roofing large
areas. Nowadays as we can see are used frequently by the designers who realize the
advantages and the impressive beauty of this form of construction. Domes have been used in
architecture since the earliest times. Braced steel dome structures have been widely used all
over the world during last three decades. Some examples of braced steel domes in the world
are shown in Figure 2.1 and Figure 2.2.
Figure 2.1: Nagoya Dome, Japan (Source: World Stadiums.com)
8
Figure 2.2: The Bloudel Conservatory, Queen Elizabeth Park, Vancouver/Canada(Source: Venture Vancouver.com)
The curvature of any point is of the same sign in all direction in a dome is a typical
example of a synclastic surface. The synclastic surfaces are also called surfaces of positive
Gaussian curvature and are not developable, such as the domic surfaces cannot be flattened
into a plane without stretching or shrinking it. This is become the reasons, domes cannot be
built from members all of the same length.
Most domes built in practice have a surface which can be generated by the rotation
of a plane curve around a vertical line. The rotating curve is called its meridian and the
horizontal. Section are known as the parallels. Any curve can be used as a meridian, while a
circle gives rise to a sphere, an ellipse to an ellipsoid of revolution and a parabola to a
rotational paraboloid. The three afore-mentioned surface are all synclastic.
In an earlier study published by the Makowski in 1962, braced domes were classified
into ten principal types, that are Ribbed domes, Schwedler domes, Lamella domes, Network
domes, Plate-type domes, Zimmermann domes, Stiffly Jointed Framed domes, Kiewitt
domes, Two-way and Three-way Grid domes and Geodesic domes. However, in this research
would narrow down the analysis to three type of domes which are Ribbed domes, Schwedler
domes and Lamella domes as shown in Figure 2.3, Figure 2.4 and Figure 2.5.
9
Figure 2.3: Ribbed Domes (Source: www.pages.drexel.edu)
Figure 2.4: Schwedler Domes (Source: www.pages.drexel.edu)
Figure 2.5: Lamella Domes (Source: www.pages.drexel.edu)
10
2.2.1 Ribbed Domes
Ribbed domes member commonly made up by solid ribs. The solid rib will
interconnected to the crown and at the foundation will be stiffened by a tension ring. Ribbed
domes which are now often used and are frequently constructed in prefabricated tubular
arched rib units. They generally interconnect at the crown and a tension ring at the foundation
stiffen the ribs. A ribbed dome will not be structurally stable unless it is designed as rigidly-
jointed system, since it does not have diagonal elements structure.
Figure 2.6: Montan State College Dome (Source: www.glulam.co.uk)
2.2.2 Schwedler Domes
A schwedler dome made up of meridional ribs. The meridional rib connected to
horizontal polygonal rings. To stiffen the resulting structure so that it will be able also to take
unsymmetric loads, each trapezium formed by intersecting meridional ribs with horizontal
rings is subdivided into two triangles by the introduction of a diagonal member as shown in
Figure 2.7.
J.W. Schwedler, a German engineer, who introduced this type of dome in 1863, built
numerous braced domes during his lifetime. The great popularity of Schwedler domes is due
11
to the fact that, on the assumption of pin-connected joints, these structures can be regarded
as statically determinate. In practice, the ribs are continuous members and the rings are
rigidly jointed, in addition to axial forces, all the members are also under the action of
bending and torsional moments.
Figure 2.7: Cinesphere - Ontario Place (Source: www.soto.on.ca)
2.2.3 Lamella Domes
The lamella dome made up of many similar units and the arrangement pattern is in a
diamond. Each lamella unit has a length which is twice the length of the side of a diamond.
To triangulate the diamond, the purlins were used in order to complete the stability that need
by the surface of the dome. The lamella domes are renowned due to their exceptionally good
behaviour under excessive wind loadings, as well as in fire and seismic disturbances.
12
Figure 2.8: Stadium in Houston, Texas (Source: www.columbia.edu)
Figure 2.9: Astrodome (Steel Lamella Dome), Houston/USA (Source: www.columbia.edu)
2.3 GRID
The element demanding one or more planar layers in structural system in order to
consider as a grid. Commonly used grid are known as single layer grid, double layer grid and
biform grid. As in this research would use the single layer grid which is also called as flat
grid. A single layer grid consists of a planar arrangement of rigidly connected beam elements.
The external loading system for a flat grid consists of forces perpendicular to the plane of the
grid and moment whose axes lie in the plane of the grid (Bulendaa T., Knippers J.. 2001).
The reason for classification of a flat grid as a space structure is that its external loads and
displacements do not lie in the plane that contains its configuration.
13
There are many type of grid patterns that are frequently used in practice. The most
basic type of grid pattern is two-way grid, while other type of grid pattern are normally
derived by removal of some elements from the basic patterns. Therefore, as in this research
will include those various type grid pattern, the pattern are two-way grid, three-way grid and
four-way grid.
2.3.1 Two-way Grid
A number of basic grid pattern are illustrated in Figure 2.10 and 2.11, which is both
are two-way grid pattern. The two-way grid pattern in Figure 2.10 is the simplest pattern for
a flat grid also called as rectangular grid. It consists of two sets of interconnected beams that
run parallel to the boundary lines. While Figure 2.11 shown a diagonal grid pattern that is
consists of two parallel sets of interconnected beams that are disposed oblique with respect
to the boundary lines.
Figure 2.10: Rectangular grid Figure 2.11: Diagonal grid
(Source: www.fgg.uni-lj.si)
2.3.2 Three-way Grid
Figure 2.12 and Figure 2.13 show some basic three-way grid pattern. The grid pattern
in these figure is obtained from a derived by removal or by adding of some elements from
the basic pattern of two-way grid. It will produce three axes in the plane of grid which will
consist three parallel sets of interconnected beams. Mostly the three-way grid pattern will
create triangle shape in the structural system. These grids are formed of a series of struts each